Experimental and DFT Study of Monensinate and Salinomycinate Complexes Containing {Fe 3 (µ 3 -O)} 7+ Core.
Nikolay PetkovAlia TadjerElzhana EnchevaZara Cherkezova-ZhelevaDaniela PanevaRadostina K StoyanovaRositsa KukevaPetar DorkovIvayla PantchevaPublished in: Molecules (Basel, Switzerland) (2024)
Two trinuclear oxo-centred iron(III) coordination compounds of monensic and salinomycinic acids (HL) were synthesized and their spectral properties were studied using physicochemical/thermal methods (FT-IR, TG-DTA, TG-MS, EPR, Mössbauer spectroscopy, powder XRD) and elemental analysis. The data suggested the formation of [Fe 3 (µ 3 -O)L 3 (OH) 4 ] and the probable complex structures were modelled using the DFT method. The computed spectral parameters of the optimized constructs were compared to the experimentally measured ones. In each complex, three metal centres were joined together at the axial position by a μ 3 -O unit to form a {Fe 3 O} 7+ core. The antibiotics monoanions served as bidentate ligands through the carboxylate and hydroxyl groups located at the termini. The carboxylate moieties played a dual role bridging each two metal centres. Hydroxide anions secured the overall neutral character of the coordination species. Mössbauer spectra displayed asymmetric quadrupole doublets that were consistent with the existence of two types of high-spin iron(III) sites with different environments-two Fe[O 5 ] and one Fe[O 6 ] centres. The solid-state EPR studies confirmed the +3 oxidation state of iron with a total spin S t = 5/2 per trinuclear cluster. The studied complexes are the first iron(III) coordination compounds of monensin and salinomycin reported so far.
Keyphrases
- solid state
- density functional theory
- iron deficiency
- mass spectrometry
- optical coherence tomography
- single molecule
- room temperature
- high resolution
- multiple sclerosis
- molecular dynamics
- ionic liquid
- molecular docking
- machine learning
- hydrogen peroxide
- magnetic resonance
- computed tomography
- gold nanoparticles
- crystal structure
- reduced graphene oxide
- dual energy
- molecular dynamics simulations
- genetic diversity
- deep learning
- contrast enhanced